/*
 * Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
 *
 * SPDX-License-Identifier: BSD-3-Clause
 */

#ifndef _HARDWARE_TIMER_H
#define _HARDWARE_TIMER_H

#include "pico.h"
#include "hardware/structs/timer.h"
#include "hardware/regs/intctrl.h"

#ifdef __cplusplus
extern "C" {
#endif

/** \file hardware/timer.h
 *  \defgroup hardware_timer hardware_timer
 *
 * \brief Low-level hardware timer API
 *
 * This API provides medium level access to the timer HW.
 * See also \ref pico_time which provides higher levels functionality using the hardware timer.
 *
 * The timer peripheral on RP-series microcontrollers supports the following features:
 *  - RP2040 single 64-bit counter, incrementing once per microsecond
 *  - RP2350 two 64-bit counters, ticks generated from the tick block
 *  - Latching two-stage read of counter, for race-free read over 32 bit bus
 *  - Four alarms: match on the lower 32 bits of counter, IRQ on match.
 *
 * \if rp2040_specific
 * On RP2040, by default the timer uses a one microsecond reference that is generated in the Watchdog (see RP2040 Datasheet Section 4.8.2) which is derived
 * from the clk_ref.
 * \endif
 *
 * \if rp2350_specific
 * On RP2350, by default the timer uses a one microsecond reference that is generated by the tick block (see RP2350 Datasheet Section 8.5)
 * \endif
 *
 * The timer has 4 alarms, and can output a separate interrupt for each alarm. The alarms match on the lower 32 bits of the 64
 * bit counter which means they can be fired a maximum of 2^32 microseconds into the future. This is equivalent to:
 *  - 2^32 ÷ 10^6: ~4295 seconds
 *  - 4295 ÷ 60: ~72 minutes
 *
 * The timer is expected to be used for short sleeps, if you want a longer alarm see the \ref hardware_rtc functions.
 *
 * \subsection timer_example Example
 * \addtogroup hardware_timer
 *
 * \include hello_timer.c
 *
 * \see pico_time
 */

// PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_HARDWARE_TIMER, Enable/disable assertions in the hardware_timer module, type=bool, default=0, group=hardware_timer
#ifndef PARAM_ASSERTIONS_ENABLED_HARDWARE_TIMER
#ifdef PARAM_ASSERTIONS_ENABLED_TIMER // backwards compatibility with SDK < 2.0.0
#define PARAM_ASSERTIONS_ENABLED_HARDWARE_TIMER PARAM_ASSERTIONS_ENABLED_TIMER
#else
#define PARAM_ASSERTIONS_ENABLED_HARDWARE_TIMER 0
#endif
#endif

/**
 * \def TIMER_NUM(timer)
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the timer number for a timer instance
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef TIMER_NUM
#if NUM_GENERIC_TIMERS == 1
#define TIMER_NUM(timer) ({ (void) (timer); 0; })
#elif NUM_GENERIC_TIMERS == 2
#define TIMER_NUM(timer) ((timer) == timer1_hw)
#endif
#endif

/**
 * \def TIMER_INSTANCE(timer_num)
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the timer instance with the given timer number
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef TIMER_INSTANCE
#if NUM_GENERIC_TIMERS == 1
#define TIMER_INSTANCE(num) timer_hw
#elif NUM_GENERIC_TIMERS == 2
#define TIMER_INSTANCE(num) ((num) ? timer1_hw : timer0_hw)
#endif
#endif

/**
 * \def TIMER_ALARM_IRQ_NUM(timer,alarm_num)
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the \ref irq_num_t for the alarm interrupt from the given alarm on the given timer instance
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef TIMER_ALARM_IRQ_NUM
#if NUM_GENERIC_TIMERS == 1
static_assert(TIMER_IRQ_3 == TIMER_IRQ_0 + 3, "");
#define TIMER_ALARM_IRQ_NUM(timer, alarm_num) ({ ((void)(timer)); (TIMER_IRQ_0 + (alarm_num)); })
#else
static_assert(TIMER1_IRQ_3 == TIMER0_IRQ_0 + 7, "");
#define TIMER_ALARM_IRQ_NUM(timer, alarm_num) (TIMER0_IRQ_0 + TIMER_NUM(timer) * NUM_ALARMS + (alarm_num))
#endif
#endif

/**
 * \def TIMER_ALARM_NUM_FROM_IRQ(irq_num)
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the alarm number from an \ref irq_num_t. See \ref TIMER_INSTANCE_NUM_FROM_IRQ to get the timer instance number
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef TIMER_ALARM_NUM_FROM_IRQ
#if NUM_GENERIC_TIMERS == 1
static_assert(TIMER_IRQ_3 == TIMER_IRQ_0 + 3, "");
#define TIMER_ALARM_NUM_FROM_IRQ(irq_num) (((irq_num) - TIMER_IRQ_0) & 3u)
#else
static_assert(TIMER1_IRQ_3 == TIMER0_IRQ_0 + 7, "");
#define TIMER_ALARM_NUM_FROM_IRQ(irq_num) (((irq_num) - TIMER0_IRQ_0) & 3u)
#endif
#endif

/**
 * \def TIMER_NUM_FROM_IRQ(irq_num)
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the alarm number from an \ref irq_num_t. See \ref TIMER_INSTANCE_NUM_FROM_IRQ to get the alarm number
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef TIMER_NUM_FROM_IRQ
#if NUM_GENERIC_TIMERS == 1
static_assert(TIMER_IRQ_3 == TIMER_IRQ_0 + 3, "");
#define TIMER_NUM_FROM_IRQ(irq_num) (((irq_num) - TIMER_IRQ_0) >> 2)
#else
static_assert(TIMER1_IRQ_3 == TIMER0_IRQ_0 + 7, "");
#define TIMER_NUM_FROM_IRQ(irq_num) (((irq_num) - TIMER0_IRQ_0) >> 2)
#endif
#endif

// PICO_CONFIG: PICO_DEFAULT_TIMER, Timer instance number to use for RP2040-period hardware_timer APIs that assumed a single timer instance, min=0, max=1, default=0, group=hardware_timer

/**
 * \ingroup hardware_timer
 * \brief The default timer instance number of the timer instance used for APIs that don't take an explicit timer instance
 * \if rp2040_specific
 * On RP2040 this must be 0 as there is only one timer instance
 * \endif
 * \if rp2350_specific
 * On RP2040 this may be set to 0 or 1
 * \endif
 */
#ifndef PICO_DEFAULT_TIMER
#define PICO_DEFAULT_TIMER 0
#endif

/**
 * \def PICO_DEFAULT_TIMER_INSTANCE()
 * \ingroup hardware_timer
 * \hideinitializer
 * \brief Returns the default timer instance on the platform based on the setting of PICO_DEFAULT_TIMER
 *
 * Note this macro is intended to resolve at compile time, and does no parameter checking
 */
#ifndef PICO_DEFAULT_TIMER_INSTANCE
#if NUM_GENERIC_TIMERS == 1
#if PICO_DEFAULT_TIMER
#error Setting PICO_DEFAULT_TIMER to non zero is meaningless as there is only one TIMER instance on this platform
#endif
#define PICO_DEFAULT_TIMER_INSTANCE() timer_hw
#else
#define PICO_DEFAULT_TIMER_INSTANCE() (__CONCAT(__CONCAT(timer,PICO_DEFAULT_TIMER), _hw))
// also define timer_hw for backwards compatibility (just accesses the default instance)
#define timer_hw PICO_DEFAULT_TIMER_INSTANCE()
#endif
#endif

static inline void check_hardware_alarm_num_param(__unused uint alarm_num) {
    invalid_params_if(HARDWARE_TIMER, alarm_num >= NUM_ALARMS);
}

/*! \brief Return a 32 bit timestamp value in microseconds for a given timer instance
*  \ingroup hardware_timer
*
* Returns the low 32 bits of the hardware timer.
* \note This value wraps roughly every 1 hour 11 minutes and 35 seconds.
*
* \param timer the timer instance
* \return the 32 bit timestamp
* \sa time_us_32
*/
static inline uint32_t timer_time_us_32(timer_hw_t *timer) {
    return timer->timerawl;
}

/*! \brief Return a 32 bit timestamp value in microseconds for the default timer instance
*  \ingroup hardware_timer
*
* Returns the low 32 bits of the hardware timer.
* \note This value wraps roughly every 1 hour 11 minutes and 35 seconds.
*
* \return the 32 bit timestamp
* \sa timer_time_us_32
*/
static inline uint32_t time_us_32(void) {
    return timer_time_us_32(PICO_DEFAULT_TIMER_INSTANCE());
}

/*! \brief Return the current 64 bit timestamp value in microseconds for a given timer instance
*  \ingroup hardware_timer
*
* Returns the full 64 bits of the hardware timer. The \ref pico_time and other functions rely on the fact that this
* value monotonically increases from power up. As such it is expected that this value counts upwards and never wraps
* (we apologize for introducing a potential year 5851444 bug).
*
* \param timer the timer instance
* \return the 64 bit timestamp
* \sa time_us_64
*/
uint64_t timer_time_us_64(timer_hw_t *timer);

/*! \brief Return the current 64 bit timestamp value in microseconds for the default timer instance
*  \ingroup hardware_timer
*
* Returns the full 64 bits of the hardware timer. The \ref pico_time and other functions rely on the fact that this
* value monotonically increases from power up. As such it is expected that this value counts upwards and never wraps
* (we apologize for introducing a potential year 5851444 bug).
*
* \return the 64 bit timestamp
* \sa timer_time_us_64
* */
uint64_t time_us_64(void);

/*! \brief Busy wait wasting cycles for the given (32 bit) number of microseconds using the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param delay_us delay amount in microseconds
 * \sa busy_wait_us_32
 */
void timer_busy_wait_us_32(timer_hw_t *timer, uint32_t delay_us);

/*! \brief Busy wait wasting cycles for the given (32 bit) number of microseconds using the default timer instance
 *  \ingroup hardware_timer
 *
 * \param delay_us delay amount in microseconds
 * \sa timer_busy_wait_us_32
 */
void busy_wait_us_32(uint32_t delay_us);

/*! \brief Busy wait wasting cycles for the given (64 bit) number of microseconds using the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param delay_us delay amount in microseconds
 * \sa busy_wait_us
 */
void timer_busy_wait_us(timer_hw_t *timer, uint64_t delay_us);

/*! \brief Busy wait wasting cycles for the given (64 bit) number of microseconds using the default timer instance
 *  \ingroup hardware_timer
 *
 * \param delay_us delay amount in microseconds
 * \sa timer_busy_wait_us
 */
void busy_wait_us(uint64_t delay_us);

/*! \brief Busy wait wasting cycles for the given number of milliseconds using the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param delay_ms delay amount in milliseconds
 * \sa busy_wait_ms
 */
void timer_busy_wait_ms(timer_hw_t *timer, uint32_t delay_ms);

/*! \brief Busy wait wasting cycles for the given number of milliseconds using the default timer instance
 *  \ingroup hardware_timer
 *
 * \param delay_ms delay amount in milliseconds
 * \sa timer_busy_wait_ms
 */
void busy_wait_ms(uint32_t delay_ms);

/*! \brief Busy wait wasting cycles until after the specified timestamp using the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param t Absolute time to wait until
 * \sa busy_wait_until
 */
void timer_busy_wait_until(timer_hw_t *timer, absolute_time_t t);

/*! \brief Busy wait wasting cycles until after the specified timestamp using the default timer instance
 *  \ingroup hardware_timer
 *
 * \param t Absolute time to wait until
 * \sa timer_busy_wait_until
 */
void busy_wait_until(absolute_time_t t);

/*! \brief Check if the specified timestamp has been reached on the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param t Absolute time to compare against current time
 * \return true if it is now after the specified timestamp
 * \sa time_reached
 */
static inline bool timer_time_reached(timer_hw_t *timer, absolute_time_t t) {
    uint64_t target = to_us_since_boot(t);
    uint32_t hi_target = (uint32_t)(target >> 32u);
    uint32_t hi = timer->timerawh;
    return (hi >= hi_target && (timer->timerawl >= (uint32_t) target || hi != hi_target));
}

/*! \brief Check if the specified timestamp has been reached on the default timer instance
 *  \ingroup hardware_timer
 *
 * \param t Absolute time to compare against current time
 * \return true if it is now after the specified timestamp
 * \sa timer_time_reached
 */
static inline bool time_reached(absolute_time_t t) {
    return timer_time_reached(PICO_DEFAULT_TIMER_INSTANCE(), t);
}

/*! Callback function type for hardware alarms
 *  \ingroup hardware_timer
 *
 * \param alarm_num the hardware alarm number
 * \sa hardware_alarm_set_callback()
 */
typedef void (*hardware_alarm_callback_t)(uint alarm_num);

/*! \brief cooperatively claim the use of this hardware alarm_num on the given timer instance
 *  \ingroup hardware_timer
 *
 * This method hard asserts if the hardware alarm is currently claimed.
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm to claim
 * \sa hardware_alarm_claim
 * \sa hardware_claim
 */
void timer_hardware_alarm_claim(timer_hw_t *timer, uint alarm_num);

/*! \brief cooperatively claim the use of this hardware alarm_num on the default timer instance
 *  \ingroup hardware_timer
 *
 * This method hard asserts if the hardware alarm is currently claimed.
 *
 * \param alarm_num the hardware alarm to claim
 * \sa timer_hardware_alarm_claim
 * \sa hardware_claim
 */
void hardware_alarm_claim(uint alarm_num);

/*! \brief cooperatively claim the use of a hardware alarm_num on the given timer instance
 *  \ingroup hardware_timer
 *
 * This method attempts to claim an unused hardware alarm
 *
 * \param timer the timer instance
 * \param required if true the function will panic if none are available
 * \return alarm_num the hardware alarm claimed or -1 if required was false, and none are available
 * \sa hardware_alarm_claim_unused
 * \sa hardware_claim
 */
int timer_hardware_alarm_claim_unused(timer_hw_t *timer, bool required);

/*! \brief cooperatively claim the use of a hardware alarm_num on the default timer instance
 *  \ingroup hardware_timer
 *
 * This method attempts to claim an unused hardware alarm
 *
 * \param required if true the function will panic if none are available
 * \return alarm_num the hardware alarm claimed or -1 if required was false, and none are available
 * \sa timer_hardware_alarm_claim_unused
 * \sa hardware_claim
 */
int hardware_alarm_claim_unused(bool required);

/*! \brief cooperatively release the claim on use of this hardware alarm_num on the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm to unclaim
 * \sa hardware_alarm_unclaim
 * \sa hardware_claim
 */
void timer_hardware_alarm_unclaim(timer_hw_t *timer, uint alarm_num);

/*! \brief cooperatively release the claim on use of this hardware alarm_num on the default timer instance
 *  \ingroup hardware_timer
 *
 * \param alarm_num the hardware alarm to unclaim
 * \sa timer_hardware_alarm_unclaim
 * \sa hardware_claim
 */
void hardware_alarm_unclaim(uint alarm_num);

/*! \brief Determine if a hardware alarm has been claimed on the given timer instance
 *  \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm number
 * \return true if claimed, false otherwise
 * \sa hardware_alarm_is_claimed
 * \sa hardware_alarm_claim
 */
bool timer_hardware_alarm_is_claimed(timer_hw_t *timer, uint alarm_num);

/*! \brief Determine if a hardware alarm has been claimed on the default timer instance
 *  \ingroup hardware_timer
 *
 * \param alarm_num the hardware alarm number
 * \return true if claimed, false otherwise
 * \sa timer_hardware_alarm_is_claimed
 * \sa hardware_alarm_claim
 */
bool hardware_alarm_is_claimed(uint alarm_num);

/*! \brief Enable/Disable a callback for a hardware alarm for a given timer instance on this core
 *  \ingroup hardware_timer
 *
 * This method enables/disables the alarm IRQ for the specified hardware alarm on the
 * calling core, and set the specified callback to be associated with that alarm.
 *
 * This callback will be used for the timeout set via hardware_alarm_set_target
 *
 * \note This will install the handler on the current core if the IRQ handler isn't already set.
 * Therefore the user has the opportunity to call this up from the core of their choice
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm number
 * \param callback the callback to install, or NULL to unset
 *
 * \sa hardware_alarm_set_callback
 * \sa timer_hardware_alarm_set_target()
 */
void timer_hardware_alarm_set_callback(timer_hw_t *timer, uint alarm_num, hardware_alarm_callback_t callback);

/*! \brief Enable/Disable a callback for a hardware alarm on the default timer instance on this core
 *  \ingroup hardware_timer
 *
 * This method enables/disables the alarm IRQ for the specified hardware alarm on the
 * calling core, and set the specified callback to be associated with that alarm.
 *
 * This callback will be used for the timeout set via hardware_alarm_set_target
 *
 * \note This will install the handler on the current core if the IRQ handler isn't already set.
 * Therefore the user has the opportunity to call this up from the core of their choice
 *
 * \param alarm_num the hardware alarm number
 * \param callback the callback to install, or NULL to unset
 *
 * \sa timer_hardware_alarm_set_callback
 * \sa hardware_alarm_set_target()
 */
void hardware_alarm_set_callback(uint alarm_num, hardware_alarm_callback_t callback);

/**
 * \brief Set the current target for a specific hardware alarm on the given timer instance
 * \ingroup hardware_timer
 *
 * This will replace any existing target
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm number
 * \param t the target timestamp
 * \return true if the target was "missed"; i.e. it was in the past, or occurred before a future hardware timeout could be set
 * \sa hardware_alarm_set_target
 */
bool timer_hardware_alarm_set_target(timer_hw_t *timer, uint alarm_num, absolute_time_t t);

/**
 * \brief Set the current target for the specified hardware alarm on the default timer instance
 * \ingroup hardware_timer
 *
 * This will replace any existing target
 *
 * \param alarm_num the hardware alarm number
 * \param t the target timestamp
 * \return true if the target was "missed"; i.e. it was in the past, or occurred before a future hardware timeout could be set
 * \sa timer_hardware_alarm_set_target
 */
bool hardware_alarm_set_target(uint alarm_num, absolute_time_t t);

/**
 * \brief Cancel an existing target (if any) for a specific hardware_alarm on the given timer instance
 * \ingroup hardware_timer
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm number
 * \sa hardware_alarm_cancel
 */
void timer_hardware_alarm_cancel(timer_hw_t *timer, uint alarm_num);

/**
 * \brief Cancel an existing target (if any) for the specified hardware_alarm on the default timer instance
 * \ingroup hardware_timer
 *
 * \param alarm_num the hardware alarm number
 * \sa timer_hardware_alarm_cancel
 */
void hardware_alarm_cancel(uint alarm_num);

/**
 * \brief Force and IRQ for a specific hardware alarm on the given timer instance
 * \ingroup hardware_timer
 *
 * This method will forcibly make sure the current alarm callback (if present) for the hardware
 * alarm is called from an IRQ context after this call. If an actual callback is due at the same
 * time then the callback may only be called once.
 *
 * Calling this method does not otherwise interfere with regular callback operations.
 *
 * \param timer the timer instance
 * \param alarm_num the hardware alarm number
 * \sa hardware_alarm_force_irq
 */
void timer_hardware_alarm_force_irq(timer_hw_t *timer, uint alarm_num);

/**
 * \brief Force and IRQ for a specific hardware alarm on the default timer instance
 * \ingroup hardware_timer
 *
 * This method will forcibly make sure the current alarm callback (if present) for the hardware
 * alarm is called from an IRQ context after this call. If an actual callback is due at the same
 * time then the callback may only be called once.
 *
 * Calling this method does not otherwise interfere with regular callback operations.
 *
 * \param alarm_num the hardware alarm number
 * \sa timer_hardware_alarm_force_irq
 */
void hardware_alarm_force_irq(uint alarm_num);

/**
 * \ingroup hardware_timer
 * \brief Returns the \ref irq_num_t for the alarm interrupt from the given alarm on the given timer instance
 * \param timer the timer instance
 * \param alarm_num the alarm number
 * \sa TIMER_ALARM_IRQ_NUM
 */
static inline uint timer_hardware_alarm_get_irq_num(timer_hw_t *timer, uint alarm_num) {
    check_hardware_alarm_num_param(alarm_num);
    return TIMER_ALARM_IRQ_NUM(timer, alarm_num);
}

/**
 * \ingroup hardware_timer
 * \brief Returns the \ref irq_num_t for the alarm interrupt from the given alarm on the default timer instance
 * \param alarm_num the alarm number
 */
static inline uint hardware_alarm_get_irq_num(uint alarm_num) {
    return timer_hardware_alarm_get_irq_num(PICO_DEFAULT_TIMER_INSTANCE(), alarm_num);
}

/**
 * \ingroup hardware_timer
 * \brief Returns the timer number for a timer instance
 *
 * \param timer the timer instance
 * \return the timer number
 * \sa TIMER_NUM
 */
static inline uint timer_get_index(timer_hw_t *timer) {
    return TIMER_NUM(timer);
}

/**
 * \ingroup hardware_timer
 * \brief Returns the timer instance with the given timer number
 *
 * \param timer_num the timer number
 * \return the timer instance
 */
static inline timer_hw_t *timer_get_instance(uint timer_num) {
    invalid_params_if(HARDWARE_TIMER, timer_num >= NUM_GENERIC_TIMERS);
    return TIMER_INSTANCE(timer_num);
}

#ifdef __cplusplus
}
#endif
#endif
